DE19922811A1 - Dewatering device for fixed surfaces and building structures, - Google Patents

Abstract

The outflow conduit (13) issues outside the surface (11c) and below the mouth (13a) of the outflow conduit. A guide device (14) is arranged, by which the water flow (WS) coming from the outflow conduit is widenable in its dimensions crossways to the flow direction. The water flow is divisible into several part flows running at least partly in different directions. The guide device is a guide plate (15) which has a catchment basin into which the water flow can be conducted. At least one guide channel leads on from the catchment basin. Several guide channels are provided, which are connected in parallel in a flow technique manner.

Description

The invention relates to a drainage device for paved surfaces and structures, especially Fahrwe ge and trough-like structures, with a drain pipe, an on or near the area to be drained has barrel and opens outside the surface.

For some structures that were fortified Areas around traffic routes such as roads or Railways or buildings can be, it is possible due to the structural framework that rainwater accumulates and is discharged got to. This is particularly important at wannenarti ge structures, such as groundwater tanks, protection tubs or driveway troughs, of which follow in which should be assumed as an example without the Invention is limited to this.

In order to do this in the rain or other precipitation tub-like structure or water entering the tub Being able to drain away continuously is a lot in the tub number of drain pipes integrated through which the water  can flow out of the tub interior (DE 295 08 704 U1). The draining water is usually one neighboring drainage ditch, which serves as a drain fed, which often runs next to the tub and against above this is canceled. It has been shown that the Water emerging from the drain pipe into the gust body and thus the foundation of the tub seeps in, so that at correspondingly low temperatures there is an increased risk of frost damage. In addition, the leads from the drain pipe de Water flow towards the embankment over time significant flushing or erosion.

An attempt has been made (DE 19 62 540 U1), the drainage channel a channel drain and the water with to be fed to the receiving water. Because the channel gutter a corresponding one to ensure the outflow Must have longitudinal inclination, the flow rate drainage water increased accordingly, so that at the end of the channel gutter there are even larger and cause erosion problems.

The invention has for its object a drainage Rungsvorrichtung for paved surfaces and structures of the to create the kind mentioned in the structurally simpler Way a good drainage while avoiding or ver reduction of rinsing and erosion guaranteed.

This object is achieved with a drainage device of the above Structure solved in that a guide device below the mouth of the drain pipe device is arranged in the form of a guide plate, by means of the water flow emerging from the drain line in their dimensions transverse to the direction of flow preferably is extensible and in several, at least Part running in different directions  flows can be subdivided, the particular per filleted baffle a catch basin into which the from the Drain pipe discharged water flow initiated and at least one that continues from the catch basin Has guide channel.

Due to the widening of the water flow are the amount of water per unit area over the Embankment is introduced into the receiving water, as well as the Flow rate of the water significantly reduced sets, which makes the mentioned flushing problems clear are diminished.

By dividing the water flow by means of the Guide plate in several in different directions Partial flows are achieved that the out of the tub amount of water flowing off not in a single water flow introduced into or on the receiving water Embankment is applied, but by the division in a variety of sub-currents beyond that run in different directions and thus on different places of the receiving water in these can be directed, the flushing and Avoid erosion problems practically completely, because the Partial flows lead such a small amount of water ren that the dynamic loads caused by the water of the individual partial flows are low are.

Continue one or more branches from the catch basin de guide channels, each of which forms a partial flow and fluidically preferably connected in parallel are. Enter the catch basin from the drain pipe The resulting water is essentially uniform the individual guide channels or partial flows distributed.  

It has proven to be advantageous if the guide channels starting from the catch basin fan-shaped apart fen and thus all different from the catch basin show directions. Leave the individual guiding channels form in a simple manner that on the Baffle plate ribs are provided, each adjacent Separate the main channels.

A further reduction in the flow rate with an additional area broadening of the flow cross-section can be achieved if in training the invention at the exit of the guide channels one each Overflow threshold is formed.

In a preferred embodiment of the invention, the guide plate with the catch basin, the guide channels and the ribs formed as a one-piece concrete component, so that this only to be placed on site needs without further rework being necessary. It has proven to be particularly beneficial if that The catch basin on the one hand and the guide channels with the ribs on the other hand in particular as separate components Prefabricated from concrete and then together at the installation site be connected or coupled. That way it is possible, the dimensions of the catch basin and the number and the dimensions and the course of the guide channels to adapt to the expected amount of water to be drained off sen in order to optimize the drainage of precipitation to care.

To slow down the flow of water, According to the invention, the guide channels can at least be turned off be roughened in sections on the surface. Alternatively or in addition to this, it can be provided that the guide Provide channels with locks at least in sections that reduce the flow of water  Zen. These can be flow baffles, however, a particularly simple embodiment is given if the guide channels are at least partially covered with sand and / or gravel are filled, so that these fillings Form locks.

The baffle will preferably drain next to that the surface or tub laid on the ground. In particular especially with traffic routes are in this peripheral area often walked paths. The guide plate can be in the walkable path will be integrated if so on the earth is laid on or embedded in it, that their surface smooth into the neighboring Erdbodenbe rich passes.

As already mentioned, the lower to be derived is whipped water often in a side next to the draining surface or tub draining drainage trench initiated. Damage to the embankment of the Drainage ditch or dam, in particular a roadway dam can be avoided according to the invention if the guide plate is on the embankment crown of the Drainage ditch is laid up and up to the over walk into the slope slope.

After the water passes the guide plate and out of the Leading channels in a widened area has emerged, it runs in particular over the slope slope Drainage ditch too. Here too, the Fließge speed of the water should be as low as possible in order to Avoid rinsing and erosion. For this Basically, it is provided according to the invention that the downstream Leitplatte and in particular on the slope of the slope Drainage ditch flow delay elements arranged are. In a preferred embodiment, the flow delays approximately elements perpendicular to the flow  direction arranged blocking plates formed in several, one behind the other in the direction of flow Rows are arranged. The locking plates must be from the Water flows around, the total water flow divided on each locking plate and thus large area is distributed. In particular, it has proven to be advantageous proven several spaced locking plates in each row to be arranged side by side, with the locking plates on each other other rows across the flow direction who are offset. This way is for the water given a labyrinthine flow path that a Ver reduction in flow rate and at the same time a Widening of the overflowed embankment area. Both the mutual spacing of the lock plate a row as well as the mutual distance successive rows vary to the geometri conditions to the soil conditions and to be able to adjust the amount of water.

The locking plates can be made of flat plastic or recycled material, but it is also possible, the dwell time of the water on the locking plates to increase to the extent desired that the side Chen outer edges of the locking plate against the flow direction are bent so that each locking plate must first collect a predetermined amount of water, before the bent outer edges are overflowed can. In this way it is ensured that the Locking plates a constant infiltration of water in the Sloping slope takes place.

The locking plates can be suitably in the Gö be anchored, especially for this purpose dimensioned pegs are used.

Further details and features of the invention are from  the following description of an embodiment with reference to the drawing. It shows gene:

Fig. 1 shows a section through a fiction, modern dewatering device in a trough-like structure,

Fig. 2 is a plan view of a guide plate,

Fig. 3 shows the section III-III in Fig. 2,

Fig. 4 shows the section IV-IV in Fig. 2 and

Fig. 5 is a top view of a drainage ditch.

In Fig. 1, a drainage device 10 is shown for a trough 11 , which has a bottom plate 11 a and edge caps 11 b adjoining upwards at the edge. In the edge region of the bottom plate 11 a near the inside edge of the cap 11b, a collecting channel 12 is formed which is covered by means of screen plates 12 a. The sole 11 c of the tub 11 has a slight cross slope in the direction of the collecting duct 12 , as indicated by the arrow in FIG. 1.

At the collecting channel 12 , a drain line 13 is connected, which runs with a longitudinal gradient through the edge cap 11 b and opens outside the tub 11 . Below the mouth 13 a of the drain line 13 , a Leitein device 14 in the form of a guide plate 15 is indicated, by means of which the water emerging from the drain line 13 via an embankment 19 of a drainage grave 20 can be introduced into this, the guide plate 15 over the entire width of the slope crown extends to the transition into the slope slope 19 a.

The guide plate 15 is shown in FIGS . 2 to 4 in detail. It is designed as a concrete component and has at its one end, below the mouth 13 a of the drain line 13 , a catch basin 18 , which is formed by a depression in the guide plate 15 . From the catch basin 18 , the guide plate extends with a fan-shaped widening section in the direction of the drainage trench 20 , wherein in the fan-shaped section a plurality of ribs 16 are formed which extend from the catch basin 18 to the edge of the guide plate 15 facing the drainage trench 20 stretch and run essentially radiating with respect to the mouth 13 a of the drain line 13 . A guide channel 17 is formed between each two ribs 16 , all guide channels 17 being connected in parallel in terms of flow by the arrangement of the ribs 16 , but proceeding in different directions starting from the catch basin 18 . At the end of each guide channel 17 , an overflow threshold 21 is formed, which reduces the flow rate of the water.

The water flow WS emerging from the drain line 13 is received by the catch basin 18 and is evenly distributed over the individual guide channels 17 , so that the partial flows T1, T2 shown in FIG. 2. . . are formed, which run in different directions and are introduced into the drainage ditch 20 at different points via the slope slope 19 a.

On the slope slope 19 a are several flow delay elements in the form of locking plates 23 a, 23 b and 23 c arranged downstream of the guide plate 15 , which are aligned substantially perpendicular to the direction of flow and are arranged in several rows one behind the other in the direction of flow. The arrangement and orientation of the locking plates is shown in particular in FIG. 5. It can be seen that the locking plate 23 a in the upper row facing the guide plate 15 is wider than the mouth cross section of all guide channels 17 and thus the guide plate 15 . In the second row below the first row, two locking plates 23 b are arranged, which are offset from the locking plate 23 a of the first row transversely to the flow direction and have a mutual distance transversely to the flow direction.

The underlying third row of locking plates already comprises three locking plates 23 c, which are offset from the two locking plates 23 b of the second row transversely to the flow direction and also have a mutual distance transversely to the flow direction. The flow conditions can be adapted to the terrain and the expected amount of water by a suitable choice of the mutual spacing of the locking plates in a row and the distances between the individual rows.

The water emerging from the guide channels of the guide plate 15 arrives at the slope 19 , flows down this and meets the blocking plate 23 a in the top row. Although in the present game Ausführungsbei only one locking plate 23 a is shown in the top row, here several locking plates can be arranged side by side.

On the way between the guide plate 15 and the Sperrplat te 23 a already a small portion of the water seeps into the embankment 19th The remaining surface water is stowed on the locking plate 23 a and flows on this on both sides to the ends of the locking plate 23 a.

There it follows the slope slope again and thus hits the locking plates 23 b of the second row, again a portion of the water seeping into the slope. On the locking plates 23 b of the second row, it again follows an accumulation and a separation of the water flow into two streams flowing around the locking plate 23 b. Corresponding conditions exist on the third row of locking plates 23 c. It is thus achieved that the water leaving the guide plate 15 is distributed over a large surface area of the slope slope 19 and, with a suitable choice of the geometric conditions, can also infiltrate it uniformly.

In the right-hand locking plate 23 c of the lower row in FIG. 5, the lateral outer edges 23 d are bent counter to the direction of flow, ie upwards, while the other locking plates are shown as flat plates. The bending of the outer edges 23 d means that a certain amount of water must first accumulate on the locking plates before the outer edges 23 d can be overflowed, so that a constant infiltration of water can be achieved on the locking plates. If necessary, some or all of the locking plates can be provided with correspondingly bent edges.

Claims (19)

1. Drainage device for paved surfaces and structures, in particular driveways and trough-like structures, with a drain line ( 13 ) which has an inlet ( 12 ) on or near the surface to be drained ( 11 c) and opens outside the surface ( 11 c), characterized in that below the mouth ( 13 a) of the drain line ( 13 ) there is a guide device ( 14 ) in the form of a guide plate ( 15 ) by means of which the water flow (WS) emerging from the drain line ( 13 ) transversely in its dimensions can be widened to the direction of flow and can be subdivided into a plurality of partial flows (T1, T2,...) at least partially running in different directions, the guide plate ( 15 ) being a catch basin ( 18 ) into which the water flow (WS) can be introduced, and at least has a guide channel ( 17 ) continuing from the catch basin ( 18 ). 2. Drainage device according to claim 1, characterized in that a plurality of guide channels ( 17 ) are vorgese hen, which are connected in parallel in terms of flow. 3. Dewatering device according to claim 2, characterized in that the guide channels ( 17 ) starting from the catch basin ( 18 ) fan-shaped apart. 4. Drainage device according to claim 2 or 3, characterized in that adjacent guide channels ( 17 ) by ribs ( 16 ) of the guide plate ( 15 ) are separated from each other. 5. Drainage device according to one of claims 2 to 4, characterized in that an overflow threshold ( 21 ) is ausgebil det at the outlet of the guide channels ( 17 ). 6. Drainage device according to one of claims 1 to 3, characterized in that the guide plate ( 15 ) with the catch basin ( 18 ), the guide channels ( 17 ) and the ribs ( 18 ) are formed as a one-piece concrete construction part. 7. Drainage device according to one of claims 1 to 5, characterized in that the catch basin ( 18 ) on the one hand and the guide channels ( 17 ) with the ribs ( 18 ) on the other hand are formed as separate components and coupled together. 8. Drainage device according to one of claims 1 to 7, characterized in that the guide channels ( 17 ) are roughened at least in sections on the surface. 9. Drainage device according to one of claims 1 to 8, characterized in that the guide channels ( 17 ) are at least partially provided with the Fließge speed-reducing locks. 10. Drainage device according to claim 9, characterized characterized in that the barriers of sand and / or Ballast fillings are formed. 11. Drainage device according to one of claims 1 to 10, characterized in that the guide plate ( 15 ) is placed or embedded in the ground in such a way that its surface merges smoothly into the adjacent ground areas. 12. Drainage device according to one of claims 1 to 11, characterized in that the guide plate ( 15 ) on the embankment of a drainage ditch ben ( 20 ) or a dam is placed. 13. Drainage device according to one of claims 1 to 12, characterized in that downstream of the guide plate ( 15 ) flow delay elements ( 23 a, 23 b, 23 c) are arranged. 14. Drainage device according to claim 13, characterized in that the flow delay elements ( 23 a, 23 b, 23 c) on the slope ( 19 a) of the drainage trench ( 20 ) are arranged. 15. Drainage device according to claim 13 or 14, characterized in that the flow delay elements are formed by substantially perpendicular to the flow direction arranged blocking plates ( 23 a, 23 b, 23 c) which are arranged in a plurality of rows one behind the other in the flow direction. 16. Drainage device according to claim 15, characterized in that the locking plates ( 23 a, 23 b, 23 c) successive rows are offset from one another transversely to the direction of flow. 17. Drainage device according to claim 15 or 16, characterized in that the lateral Außenenkan ten ( 23 d) of the locking plates ( 23 c) are bent against the flow direction. 18. Drainage device according to one of claims 13 to 17, characterized in that the flow delay elements ( 23 a, 23 b, 23 c) are anchored in particular by means of nails in the ground. 19. Dewatering device according to one of claims 13 to 18, characterized in that the flow delay elements ( 23 a, 23 b, 23 c) consist of plastic or of recycling material.